Cure of human carcinoma xenografts by a single dose of pretargeted yttrium-90 with negligible toxicity.

A covalent conjugate (NR-LU-10/SA) was prepared between streptavidin (SA) and NR-LU-10, a mAb that binds an antigen expressed on the surface of most human carcinomas. NR-LU-10/SA was injected into nude mice bearing human tumor xenografts. Injection of biotinylated galactosyl-human serum albumin reduced the circulating levels of conjugate by 95%. Subsequent administration of (90)Y-1,4,7, 10-tetraazacyclododecane-1,4,7,10-tetraacetic acid-biotin achieved peak uptake at the tumor within 2 hr while >80% of the radioactivity was eliminated in the urine. A single dose of 600-800 microCi of (90)Y-1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid-biotin produced cures in 10/10 mice with established (>200 mm(3)) s.c. human small cell lung or colon cancer xenografts and 8/10 cures in mice with human breast cancer xenografts without significant toxicity.

Clinical optimization of pretargeted radioimmunotherapy with antibody-streptavidin conjugate and 90Y-DOTA-biotin.

UNLABELLED: Pretargeted radioimmunotherapy (PRIT) was evaluated using an antibody-streptavidin conjugate, followed by a biotin-galactose-human serum albumin clearing agent and 90Y-dodecane tetraacetic acid (DOTA)-biotin as the final step for therapy. The objective was to develop a clinical protocol that could show an improved tumor-to-red marrow therapeutic ratio compared with conventional radioimmunotherapy (RIT) and at the same time preserve the efficiency of tumor targeting. METHOD: Forty-three patients with adenocarcinomas reactive to NR-LU-10 murine monoclonal antibody received the 3 components. Doses and timing parameters were varied to develop an optimized schema. In some patients, the conjugate was radiolabeled with 186Re as an imaging tracer to assess biodistribution of the conjugate and effectiveness of the clearing agent. 111In-DOTA-biotin was coinjected with 90Y-DOTA-biotin for quantitative imaging. Safety, biodistribution, pharmacokinetics, dosimetry, and antiglobulin formation were evaluated. RESULTS: The optimal schema was defined as a conjugate dose of 125 microg/mL plasma volume followed at 48 h by a clearing agent in a 10:1 molar ratio of clearing agent to serum conjugate. The therapeutic third step was 0.5 mg radiobiotin administered 24 h later. No significant adverse events were observed after administration of any of the components. The mean tumor-to-marrow absorbed dose ratio when using the optimized PRIT schema was 63:1, compared with a 6:1 ratio reported previously for conventional RIT. Antiglobulin to murine antibody and to streptavidin developed in most patients. CONCLUSION: This initial study confirmed that the PRIT approach is safe and feasible and achieved a higher therapeutic ratio than that achieved with conventional RIT using the same antibody.

Quantitative analysis of a synthetic peptide, NR58-3.14.3, in serum by LC-MS with inclusion of a diastereomer as internal standard.

A method for quantifying an intramolecularly linked all-d-amino acid peptide, NR58-3.14.3, in rat serum by LC-MS using selected ion monitoring with inclusion of a diastereomer as internal standard was developed. The reproducible quantitation of multiply charged compounds by LC-MS using single ion or selective reaction monitoring is often a challenge as the intensity ratio of the ions in a series of different charge states can vary. Good precision was obtained in the selected ion monitoring mode by integrating the summed ion currents of the singly, doubly, and triply charged molecular ions. Since stable isotope analogs are costly and integration of residual unlabeled material can be of concern, a diastereomer of NR58-3.14.3, NR58-3.14.5, was used as internal standard. The diastereomers were indistinguishable by electrospray MS, but fully separated by reversed-phase LC. Consequently, interference due to isotopic impurities or coelution was not encountered. The calibration plot was linear throughout a concentration range of 0.2 to 200.0 microg/ml (r(2) = 0.9996). Intraday precision of the standards analyzed was less than 12% RSD over the calibration range and the accuracy within +/-11% RE. Serum pharmacokinetics were in good agreement with the pharmacokinetic profiles of small, ionic, and polar molecules.

Molecular modeling and preclinical evaluation of the humanized NR-LU-13 antibody.

A mouse-human chimeric monoclonal antibody (chNR-LU-13), specific for the EGP40 pancarcinoma antigen, was humanized through three-dimensional molecular modeling. Humanization of the chNR-LU-13 antibody is expected to enhance its use for patients undergoing immunotherapy. On the basis of the observed amino acid sequence identity, chNR-LU-13 complementary determining regions (CDRs) of the V(L) and V(H) regions were grafted onto the human anti-DNA-associated idiotype immunoglobulin clone, R3.5H5G'CL. Ten amino acids residues within the humanized framework were back-mutated to their corresponding chNR-LU-13 sequence, because they were predicted to disrupt the canonical classification of the CDRs or were within 5 A of a CDR. Synthesis of the V(L) and V(H) regions was accomplished by recursive PCR, and the dual-chain expression vector p451.C4 was positioned under control of the CMV(P+E). We observed by competitive ELISA that the recombinant humanized NR-LU-13 (huNR-LU-13) IgG1 antibody exhibited an indistinguishable immunoreactivity profile when compared with the murine monoclonal antibody (muNR-LU-10). The huNR-LU-13 antibody was effective in mediating both antibody-dependent cellular cytotoxicity and complement-mediated cytotoxicity when assayed against either the breast carcinoma cell line, MCF-7, or the colon adenocarcinoma cell line, SW1222. Biodistribution studies using i.v. coinjected 131I-muNR-LU-10 and 125I-huNR-LU-13 confirmed that the huNR-LU-13 specifically targets to the tumor in athymic BALB/c mice bearing the SW1222 human tumor xenograft. Humanization of the chNR-LU-13 antibody is expected to eliminate an undesired human antimouse antibody response, allowing for repeated i.v. administration into humans.

Simplified preformed chelate protein radiolabeling with technetium-99m mercaptoacetamidoadipoylglycylglycine (N3S-adipate).

A simplified kiet has been developed for 99mTc protein radiolabeling using an N3S triamide mercaptide bifunctional chelating agent and the preformed chelate approach. The process combined N3S chelating agent, gluconate intermediate transfer agent, stannous reducing agent, and gentisic acid stabilizer into a lyophilized formulation. With sulfur donor atom hemithioacetal protection of the ligand, delta-2,3,5,6-tetrafluorothiophenyl alpha-S-(1-ethoxyethyl)mercaptoacetamido-L-adipoylglycylglycine , optimum 99mTc chelation was achieved in a single step. Subsequent reaction with NR-LU-10 antibody Fab fragment followed by purification via QAE Sephadex anion exchange resin filter afforded 99mTc-N3S-NR-LU-10 Fab conjugate with retained immunoreactivity and effective tumor targeting properties.

Mechanistic studies on the metabolic activation of acetaminophen in vivo.

Three analogues of acetaminophen (APAP), labeled at specific positions with either oxygen-18 or deuterium, were administered by ip injection to male BALB/c mice at the moderately hepatotoxic dose of 200 mg kg-1 in order to probe the mechanism by which APAP undergoes metabolic activation in vivo. The thioether conjugates of APAP present in bile, urine, and feces, which are believed to derive from the electrophilic intermediate N-acetyl-p-benzoquinone imine (NAPQI), were isolated following aqueous-phase derivatization, separated by HPLC, and converted to a common volatile derivative for analysis by GC-MS. The observed labeling patterns of these conjugates indicated that APAP undergoes metabolism to NAPQI by a process that does not involve the generation of a free oxygenated intermediate, but which more likely entails the sequential removal of two electrons from the substrate. On the basis of these findings, an integrated metabolic scheme is proposed which invokes initial cytochrome P-450 mediated generation of a caged oxygen-centered APAP radical species. Subsequent reactions of this intermediate may account for the formation of all known oxidative metabolites of APAP.

Covalent binding of acetaminophen to mouse hemoglobin. Identification of major and minor adducts formed in vivo and implications for the nature of the arylating metabolites.

When hepatotoxic doses of [ring-U-14C]acetaminophen ([ring-U-14C]APAP) were administered to mice, radioactivity became bound irreversibly to hemoglobin as well as to proteins in the liver and kidney. The covalent binding to hemoglobin was dose-dependent, and in phenobarbital-pretreated mice occurred to the extent of approximately 8% of the corresponding binding to liver proteins. Degradation of the modified globin by acid hydrolysis yielded 3-cystein-S-yl-4-hydroxyacetanilide as the major radioactive product, accounting for approximately 70% of protein-bound drug residues. This finding is consistent with the view that the majority of covalent binding of APAP to proteins is mediated by N-acetyl-p-benzoquinone imine (NAPQI), a reactive metabolite which preferentially arylates cysteinyl thiol residues. However, after administration of [acetyl-3H]APAP to mice, it was found that approximately 20% of the drug bound to hemoglobin had lost the N-acetyl side-chain, indicating the existence of a second type of APAP-protein adduct. One minor component of the globin hydrolysate was identified as S-(2,5-dihydroxyphenyl)-cysteine, which most likely arises from binding to hemoglobin of p-benzoquinone, a hydrolysis product of NAPQI. The two adducts reported represent the first identified examples of arylating drugs binding to hemoglobin. Experiments on the influence of different cytochrome P-450 inducing agents on the ratio of drug bound to hemoglobin versus hepatic proteins suggested that the reactive metabolites of APAP are formed in the liver and migrate to the erythrocyte, rather than being produced by hemoglobin-catalyzed oxidation of APAP. These findings imply that the reactive metabolites of APAP escape from hepatocytes in some latent forms, which then participate in the arylation of protein thiols in red blood cells and, possibly, at other remote sites.

Metabolism of N-methylformamide in mice: primary kinetic deuterium isotope effect and identification of S-(N-methylcarbamoyl)glutathione as a metabolite.

S-(N-Methylcarbamoyl)glutathione has been identified by cesium ion liquid secondary ion mass spectrometry as a biliary metabolite in mice of the experimental antitumor agent and hepatotoxin N-methylformamide. Metabolism of N-methylformamide to urinary methylamine, urinary N-acetyl-S-(N-methylcarbamoyl)-cysteine and biliary S-(N-methylcarbamoyl)glutathione was found to be subject to large intermolecular primary kinetic isotope effects when hydrogen was replaced by deuterium in the formyl group (kH/kD = 5.5 +/- 0.2, 4.5 +/- 1.0 and 7 +/- 2, respectively), as shown by mass spectrometry of derivatives of these metabolites. These values indicate the existence of a common metabolic precursor for each of these metabolites. In particular, methylamine is shown not to arise from simple enzymatic hydrolysis of N-methylformamide but is associated with an oxidative process. Therefore, it is highly likely that N-methylformamide is oxidized and conjugated to form S-(N-methylcarbamoyl)glutathione which is metabolized further to N-acetyl-S-(N-methylcarbamoyl) cysteine. Either of these thiocarbamates could be hydrolyzed to give the parent thiol and the observed metabolic end products, methylamine and carbon dioxide. The presence of deuterium in the formyl moiety of N-methylformamide reduced markedly the hepatotoxicity of the compound, as shown by measurements of the activities of appropriate hepatic enzymes in plasma.

Identification of the major covalent adduct formed in vitro and in vivo between acetaminophen and mouse liver proteins.

Improved analytical methodology has been developed for the structural characterization of covalently bound drug-protein adducts and has been applied to an investigation of the conjugates formed in vivo and in vitro between [14C]acetaminophen and mouse liver proteins. The major adduct released by acid hydrolysis of hepatic protein samples, which accounted for approximately 70% of the bound radioactivity in vivo and in vitro, was identified as 3-cystein-S-yl-4-hydroxyaniline, a derivative whose structure reflects the predominance of acetaminophen thioether adducts in drug-modified proteins. It is concluded that the reactive, electrophilic metabolite of acetaminophen, which most likely is N-acetyl-p-benzoquinoneimine, binds with a high degree of selectivity to cysteinyl thiol groups on protein, formally in a Michael-type addition reaction. Cysteine residues thus represent primary target sites for arylation by the reactive metabolite of acetaminophen, and proteins rich in free thiols may be especially vulnerable to damage by this toxic intermediate.

Structural characterization of the major covalent adduct formed in vitro between acetaminophen and bovine serum albumin.

The structure of the covalent adduct formed in vitro between [14C]-acetaminophen ([14C]APAP) and bovine serum albumin (BSA) has been investigated with the aid of new analytical methodology. The APAP-BSA adduct, isolated from mouse liver microsomal incubations to which the radiolabeled drug and BSA had been added, was cleaved using a combination of specific (cyanogen bromide) and non-specific (acid hydrolysis) procedures, following which the mixture of amino acids obtained was derivatized, in aqueous solution, with ethyl chloroformate. The resulting ethoxycarbonyl derivatives were recovered by extraction into ethylacetate, methylated and subjected to profile analysis using both reverse-phase and normal-phase HPLC techniques. In each HPLC step, one major radioactive amino acid adduct was detected and was identified by mass spectrometry as the derivative of 3-cystein-S-yl-4-hydroxyaniline. Based on this finding, and with a knowledge of the behavior under acidic hydrolysis conditions of the 3-cysteinyl conjugate of APAP, it could be concluded that the major APAP-BSA adduct is one in which the drug is bound, via a thioether linkage at the C-3 position, to a sulfhydryl group on the protein. Furthermore, it could be established that this -SH function almost certainly is that associated with the cys-34 residue of BSA.

The microsomal metabolism and site of covalent binding to protein of 3'-hydroxyacetanilide, a nonhepatotoxic positional isomer of acetaminophen.

Incubations of 3'-hydroxyacetanilide (3HAA) with hepatic microsomal preparations from phenobarbital-pretreated mice led to the formation of three products of aromatic hydroxylation, viz. 2',5'-, 3',4'-, and 2',3'-dihydroxyacetanilide, which were identified by GC/MS techniques and quantified by GLC analysis. NADPH-dependent covalent binding of radioactivity from [14C]3HAA to microsomal protein took place at almost four times the rate at which [14C]acetaminophen became irreversibly bound to protein under the same experimental conditions. This binding was inhibited by the addition to incubation media of ascorbate, glutathione, and the soluble proteins bovine serum albumin and bovine alpha s1-casein, but not by superoxide dismutase. Radioactivity from [14C]3HAA also became covalently bound to the added soluble proteins, the extent of which was greatest when the proteins contained a high content of free -SH groups. From an analysis of the effect of ascorbate and glutathione on both the covalent binding of 14C to protein and the production of the noncovalently bound products of 3HAA metabolism, it is concluded that reactive intermediates most likely derive from further oxidation of the primary 3HAA metabolites to electrophilic semiquinone and/or quinone species. Sulfhydryl groups appear to be the principal sites on protein at which covalent binding of these reactive metabolites of 3HAA takes place, a feature shared by the reactive species generated during acetaminophen metabolism.